Copper foil composite, formed product and method of producing the same

ABSTRACT

A copper foil composite comprising a copper foil and a resin layer laminated thereon, satisfying an equation 1: (f 3 ×t 3 )/(f 2 ×t 2 )=&gt;1 wherein t 2  (mm) is a thickness of the copper foil, f 2  (MPa) is a stress of the copper foil under tensile strain of 4%, t 3  (mm) is a thickness of the resin layer, f 3  (MPa) is a stress of the resin layer under tensile strain of 4%, and an equation 2: 1&lt;=33f 1 /(F×T) wherein f 1  (N/mm) is 180° peeling strength between the copper foil and the resin layer, F(MPa) is strength of the copper foil composite under tensile strain of 30%, and T (mm) is a thickness of the copper foil composite, wherein a Sn layer having a thickness of 0.2 to 3.0 μm is formed on a surface of the copper foil on which the resin layer is not laminated.

FIELD OF THE INVENTION

The present invention relates to a copper foil composite comprising a copper foil and a resin layer laminated thereon, a formed product and a method of producing the same.

DESCRIPTION OF THE RELATED ART

A copper foil composite comprising a copper foil and a resin layer laminated thereon is applied to an FPC (flexible printed circuit), an electromagnetic shielding material, an RF-ID (wireless IC tag), a sheet heating element, a heat dissipators and the like. As an example of the FPC, a copper foil circuit is formed on a base resin layer, and a coverlay film for protecting the circuit overlaps the circuit to provide a laminate structure having a resin layer/a copper foil/a resin layer.

For formability of such a copper foil composite, bending properties as represented by MIT flexibility and high cycle flexibility as represented by IPC flexibility are needed. A copper foil composite having excellent bending properties and flexibility is suggested (see Patent Literatures 1 to 3). As an example, the FPC is bent and used at a movable part such as a hinge part of a mobile phone; or for space-saving of a circuit. Its deformation mode is a uniaxial flex as represented by the above-described MIT flexibility test and IPC flexibility test. Thus, the FPC is designed not for a severe deformation mode.

When the copper foil composite is used as the electromagnetic shielding material and the like, the copper foil composite includes a laminate structure having the resin layer/the copper foil. The surface of the copper foil composite is required to provide corrosion resistance and long-term stable electric contact properties.

PRIOR ART LITERATURE Patent Literature [Patent Literature 1] Japanese Unexamined Patent Publication No. 2010-100887 [Patent Literature 2] Japanese Unexamined Patent Publication No. 2009-111203 [Patent Literature 3] Japanese Unexamined Patent Publication No. 2007-207812 SUMMARY OF THE INVENTION Problems to be Solved by the Invention

However, once the above-described copper foil composite is press-formed, it induces a severe (complex) deformation mode, which differs from that in the MIT flexibility test or the IPC flexibility test. It might cause a problem that the copper foil is broken. And, if the copper foil composite can be press-formed, a structure including a circuit can be tailored to fit a product shape.

Accordingly, an object of the present invention is to provide a copper foil composite having excellent formability while preventing a copper foil from broken, even if a severe (complex) deformation, which is different from a uniaxial flex, is induced by press forming, and providing corrosion resistance and electric contact properties stably for a long duration; a formed product and a method of producing the same.

Means for Solving the Problems

The present inventors found that when the deformation behavior of the resin layer is transmitted to the copper foil, the copper foil is deformed together with the resin layer, whereby the copper foil is hardly constricted, the ductility is increased and the crack of the copper foil is prevented. Thus, the present invention is attained. In other words, the properties of the resin layer and the copper foil are specified so that the deformation behavior of the resin layer is transmitted to the copper foil. In addition, a coating layer on the surface of the copper foil is specified so that corrosion resistance and electric contact properties are provided stably for a long duration.

That is, the present invention provides a copper foil composite comprising a copper foil and a resin layer laminated thereon, satisfying an equation 1: (f₃×t₃)/(f₂×t₂)=>1 wherein t₂ (mm) is a thickness of the copper foil, f₂ (MPa) is a stress of the copper foil under tensile strain of 4%, t₃ (mm) is a thickness of the resin layer, f₃ (MPa) is a stress of the resin layer under tensile strain of 4%, and an equation 2:1<=33f₁/(F×T) wherein f₁ (N/mm) is 180° peeling strength between the copper foil and the resin layer, F(MPa) is strength of the copper foil composite under tensile strain of 30%, and T (mm) is a thickness of the copper foil composite, wherein a Sn layer having a thickness of 0.2 to 3.0 μm is formed on a surface of the copper foil on which the resin layer is not laminated.

Preferably, the equations 1 and 2 are true at the temperature lower than the glass transition temperature of the resin layer.

Preferably, a ratio I/L of fracture strain I of the copper foil composite to fracture strain L of the resin layer alone is 0.7 to 1.

Preferably, a Ni layer or a Cu layer is formed between the Sn layer and the copper foil, or a Ni layer and a Cu layer are formed between the Sn layer and the copper foil in the order of the Ni layer and the Cu layer from the copper foil, and wherein the Ni layer and the Cu layer each have a thickness of 0.1 to 2.0 μm.

Also, the present invention provides a formed product obtained by working the copper foil composite. The formed product of the present invention can be worked sterically, for example, by a press working, bulging using a top and a bottom dies, other working with drawing.

Also, the present invention provides a method of producing a formed product comprising working the copper foil composite.

Effect of the Invention

According to the present invention, there can be provided a copper foil composite having excellent formability while preventing a copper foil from broken even if a severe (complex) deformation, which is different from a uniaxial flex, is induced by press forming, and providing corrosion resistance and long-term stable electric contact properties.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a graph showing a relationship between f₁ and (F×T) obtained by experiments; and

FIG. 2 shows a schematic configuration of a cup test device for evaluating the formability.

DETAILED DESCRIPTION OF THE INVENTION

The copper foil composite of the present invention comprises a copper foil and a resin layer laminated thereon. Non-limiting example of the usage of the copper foil composite of the present invention includes an FPC (flexible printed circuit), an electromagnetic shielding material, an RF-ID (wireless IC tag), a sheet heating element, a heat dissipator.

<Copper Foil>

The thickness t₂ of the copper foil is preferably 0.004 to 0.05 mm (4 to 50 μm). When the t₂ is less than 0.004 mm (4 μm), the ductility of the copper foil is significantly decreased, and the formability of the copper foil composite may not be improved. It is preferable that the fracture strain of the copper foil be 4% or more. When the t₂ exceeds 0.05 mm (50 μm), the properties belonging to the copper foil alone significantly appear on the copper foil composite, and the formability of the copper foil composite may not be improved.

As the copper foil, a rolled copper foil, an electro-deposited copper foil, a metallized copper foil and the like can be used. The rolled copper foil is preferable, in that it has excellent formability based on recrystallization and can decrease strength (f₂). When a treated layer is formed on the surface of the copper foil in order to provide adhesion properties and rust prevention, the treated layer is considered to be included in the copper foil.

<Resin Layer>

The resin layer is not especially limited. The resin layer may be formed by applying a resin material to the copper foil. Preferably, the resin film can be adhered to the copper foil. Examples of the resin film include a PET (polyethylene terephthalate) film, a PEN (polyethylene naphthalate), a PI (polyimide) film, an LCP (liquid crystal polymer) film and a PP (polypropylene) film.

For the lamination of the resin film and the copper foil, an adhesive agent may be used between the resin film and the copper foil, or the resin film may be thermally compressed on the resin film. When the strength of the adhesive agent layer is low, the formability of the copper foil composite is difficult to be improved. It is therefore preferable that the strength of the adhesive agent layer be ⅓ or more of the stress (f₃) of the resin layer. Since the technical idea of the present invention is to improve the ductility by transmitting the deformation behavior of the resin layer to the copper foil, by deforming the copper foil similar to the resin layer, and by preventing the necking of the copper foil. Thus, the adhesive agent layer may not be well deformed when the strength of the adhesive agent layer is low, and the behavior of the resin is not transmitted to the copper foil.

When the adhesive agent is used, the properties of the resin layer are intended to include those of the adhesive agent layer and the resin layer, as described later.

The thickness t₃ of the resin layer is preferably 0.012 to 0.12 mm (12 to 120 μm). When the t₃ is less than 0.012 mm (12 μm), (f₃×t₃)/(f₂×t₂) may be<1. When the t₃ exceeds 0.12 mm (120 μm), the flexibility of the resin layer is decreased, the stiffness becomes too high, and the formability is degraded. It is preferable that the fracture strain of the resin layer be 40% or more.

<Copper Foil Composite>

The combination of the copper foil composite comprising the copper foil and the resin layer laminated thereon described above includes a two-layer structure such as the copper foil/the resin layer or a three-layer structure such as the copper foil/the resin layer/the copper foil. In case of (the copper foil/the resin layer/the copper foil) where the copper foils are disposed on both sides of the resin layer, the total value of (f₂×t₂) is obtained by adding each value of (f₂×t₂) calculated about the two copper foils.

<180° Peeling Strength>

Since the copper foil is thin, necking is easily occurred in a thickness direction. When the necking is produced, the copper foil is broken and the ductility is therefore decreased. On the other hand, the resin layer has a property that the necking is difficult to be produced when tension is applied (i.e., the resin layer has a wide area with uniform strain). Thus, in the composite comprising the copper foil and the resin layer, when the deformation behavior of the resin layer is transmitted to the copper foil, the copper foil is deformed together with the resin layer, the necking of the copper foil is hardly occurred, and the ductility is increased. When the adhesion strength between the copper foil and the resin layer is low, the deformation behavior of the resin layer cannot be transmitted to the copper foil, so the ductility is not improved (the copper foil is peeled or cracked).

Then, high adhesion strength is needed. Shear bond strength is considered to be a direct indicator of the adhesion strength. If the adhesion strength is increased such that the shear bond strength has a similar level to strength of the copper foil composite, the area other than the bonding surface is broken to make a measurement difficult.

In view of the above, the value f₁ of 180° peeling strength is used. Although the absolute values of the shear bond strength and the 180° peeling strength are totally different, there is a correlation between the formability, tensile elongation and the 180° peeling strength. So, the 180° peeling strength is deemed as an indicator of the adhesion strength.

In fact, it is considered that “the strength at the time of the material is broken” is equal to “the shear bond strength.” As an example, it is considered that when 30% or more of the tensile strain is required, “30% of a flow stress <=shear bond strength.” When 50% or more of the tensile strain is required, “50% of a flow stress <=shear bond strength.” According to the experiments by the present inventors, the formability was excellent when the tensile strain exceeded 30% or more. So, the strength obtained when the tensile strain is 30% is defined as the strength F of the copper foil composite, as described later.

FIG. 1 is a graph showing a relationship between f₁ and (F×T) obtained by experiments, and plots the value of f₁ and (F×T) in each Example and Comparative Example. (F×T) is the strength applied to the copper foil composite under tensile strain of 30%. If this is regarded as the minimum shear bond strength required for increasing the formability, f₁ and (F×T) are correlated at the slope of 1 as long as the absolute values of these are same.

However, in FIG. 1, the values of f₁ and (F×T) in all data are not correlated similarly. In each Comparative Example with poor formability, the coefficient of correlation f₁ to (F×T) (in other words, the slope of f₁ to (F×T) from the origin point in FIG. 1) is gentle, and the 180° peeling strength is correspondingly poor. On the other hand, the slope of each Example is greater than that of each Comparative Example. The slope of Example 18 (just broken under the strain of 30%) is gentlest and is 1/33. Thus, this value is regarded as the correlation function between the minimum shear bond strength and the 180° peeling strength required for increasing the formability. In other words, it is considered that the shear bond strength is 33 times greater than the 180° peeling strength.

In Comparative Example 3, the slope in FIG. 1 exceeds 1/33. However, an equation 1: (f₃×t₃)/(f₂×t₂) described later is less than 1, which results in the poor formability.

The 180° peeling strength is represented by force per unit width (N/mm).

When the copper foil composite has a three-layer structure including a plurality of bonding surfaces, the lowest value of the 180° peeling strength out of the bonding surfaces is used. This is because the weakest bonding surface is peeled.

In order to increase the adhesion strength between the copper foil and the resin layer, a Cr oxide layer is formed on the surface of the copper foil (on the surface of the resin layer, herein referred to as a “bonding surface” for convenience) by a chromate treatment and so on, the surface of the copper foil is roughened, or the Cr oxide layer is disposed after the surface of the copper foil is coated with Ni or an Ni alloy layer. As described later, a Sn layer is formed on the surface (non-bonding surface) of the copper foil opposite to the resin layer. When the Sn layer is also formed on the bonding surface, the adhesion strength to the resin layer is improved.

The thickness of the Cr oxide layer may be 5 to 100 μg/dm² based on the weight of Cr. The thickness is calculated from the Cr content by wet analysis. The presence of the Cr oxide layer can be determined by X-ray photoelectron spectroscopy (XPS) for detecting Cr. (The peak of Cr is shifted by oxidation.)

The coating (attached) amount of Ni or the Ni alloy layer may be 90 to 5000 μg/dm². If the Ni coating amount exceeds 5000 μg/dm² (which corresponds to the Ni thickness of 56 nm), the advantageous effect is saturated and no more improvement cannot be provided.

Preferably, the Ni alloy layer contains 50 wt % or more of Ni and one or more of Zn, Sn, Co, Cr, Mn, V, P, B, W, Mo and Fe; the balance being incidental impurities. The Sn layer may have a thickness of 0.2 to 3.0 μm on the bonding surface of the copper foil.

Furthermore, the adhesion strength can be increased by changing the pressure and the temperature conditions when the copper foil and the resin layer are laminated and combined. Insofar as the resin is not damaged, both of the pressure and the temperature upon lamination may be increased.

On the surface of the copper foil where the resin layer is not laminated, a Sn layer having a thickness of 0.2 to 3.0 μm is formed in order to provide corrosion resistance and long-term stable electric contact properties.

If the thickness of the Sn layer is less than the lower limit, the corrosion resistance and the stable electric contact properties of the copper foil cannot be provided. On the other hand, the thicker the Sn layer is, the more the corrosion resistance and the stability of the electric contact properties are improved. However, as the advantageous effects are saturated and the costs are increased, the upper limit is determined. The thickness of the Sn layer is preferably 0.3 to 2.0 μm, more preferably 0.5 to 1.5 μm.

The Sn layer and the copper foil form a diffusion layer. In order to prevent this, a Ni layer or a Cu layer may be formed between the Sn layer and the copper foil (on the surface of the resin layer). Alternatively, between the Sn layer and the copper foil, the Ni layer and the Cu layer may be formed in the order of the Ni layer and the Cu layer from the copper foil. Preferably, the Ni layer and the Cu layer each have a thickness of 0.1 to 2.0 μm.

Between the Sn layer and the copper foil, a Ni alloy layer may be formed instead of the Ni layer. Preferably, the Ni alloy layer contains 50 wt % or more of Ni and one or more of Zn, Sn, Co, Cr, Mn, V, P, B, W, Mo and Fe; the balance being incidental impurities.

<(f₃×t₃)/(f₂×t₂)>

Next, the meaning of ((f₃×t₃)/(f₂×t₂))(hereinafter referred to as “equation 1”) in claims will be described. Since the copper foil composite comprises the copper foil and the resin layer laminated thereon, which have the same width (size), the equation 1 represents a ratio of the force applied to the copper foil to the force applied to the resin layer in the copper foil composite. When the ratio is 1 or more, much force is applied to the resin layer and the resin layer is stronger than the copper foil. As a result, the copper foil does not broken and exhibits good formability.

When (f₃×t₃)/(f₂×t₂)<1, too much force is applied to the copper foil, and the above-mentioned effects do not provided, i.e., the deformation behavior of the resin layer is not transmitted to the copper foil, and the copper foil is not deformed together with the resin.

Here, f₂ and f₃ may be the stress at the same strain amount after plastic deformation is induced. In consideration of the fracture strain of the copper foil and the strain at the time of starting the plastic deformation of the resin layer (for example, PET film), f₂ and f₃ are set to the tensile strain of 4%. The values f₂ and f₃ (and f₁) are all obtained in a MD (machine direction).

<33f₁/(F×T)>

Then, the meaning of (33f₁/(F×T)(hereinafter referred to as “equation 2”) in claims will be described. As described above, the minimum shear bond strength which directly shows the minimum adhesion strength between the copper foil and the resin layer required for increasing the formability is about 33 times greater than the 180° peeling strength f₁. In other words, 33f₁ represents the minimum adhesion strength required for improving the formability of the copper foil and the resin layer. On the other hand, (F×T) is the strength applied to the copper foil composite, and the equation 2 represents a ratio of the adhesion strength between the copper foil and the resin layer to tensile force of the copper foil composite. When the copper foil composite is pulled, a shear stress is induced by the copper foil to be deformed locally and the resin to be subjected to uniform tensile strain at an interface between the copper foil and the resin layer. Accordingly, when the adhesion strength is lower than the shear stress, the copper and the resin layer are peeled. As a result, the deformation behavior of the resin layer cannot be transmitted to the copper foil, and the ductility of the copper foil is not improved.

In other words, when the ratio in the equation 2 is less than 1, the adhesion strength is lower than the force applied to the copper foil composite, and the copper foil and the resin tend to be easily peeled. Then, the copper foil may be broken by processing such as press forming.

When the ratio in the equation 2 is 1 or more, the copper and the resin layer are not peeled, and the deformation behavior of the resin layer can be transmitted to the copper foil, thereby improving the ductility of the copper foil. The higher ratio in the equation 2 is preferable. However, it is generally difficult to provide the value of 10 or more. The upper limit in the equation 2 may be 10.

In addition, it is considered that the higher formability is, the higher the value of 33f₁/(F×T) is. However, the tensile strain I of the resin layer is not proportional to 33f₁/(F×T). This is because the effects of the magnitude of (f₃×t₃)/(f₂×t₂) and the ductility of the copper foil or the rein layer alone. However, the combination of the copper foil and the resin layer satisfying the equations: 33f₁/(F×T)=>1 and (f₃×t₃)/(f₂×t₂)=>1 can provide the composite having the required formability.

Here, the reason for using the strength obtained when the tensile strain is 30% as the strength F of the copper foil composite is that the formability was excellent when the tensile strain exceeded 30% or more, as described above. Another reason is as follows: When the copper foil composite was subjected to a tensile test, a great difference was produced in the flow stress due to the strain until the tensile strain reached 30%. However, no great difference was produced in the flow stress due to the strain after the tensile strain reached 30% (although the copper foil composite was somewhat work hardened, the slope of the curve became gentle).

When the tensile strain of the copper foil composite is less than 30%, the tensile strength of the copper foil composite is defined as F.

As described above, the copper foil composite of the present invention has excellent formability while preventing a copper foil from broken even if a severe (complex) forming, which is different from a uniaxial flex, is made by press and so on. In particular, the present invention is suitable for three-dimensional molding including press molding. When the copper foil composite is three-dimensional formed, the copper foil composite can have a complex shape and improved strength. For example, the copper foil composite itself can be a housing used in various power circuits, resulting in decreased the number of parts and costs.

<I/L>

The ratio I/L of fracture strain I of the copper foil composite to fracture strain L of the resin layer alone is preferably 0.7 to 1.

In general, the tensile fracture strain of the resin layer is significantly higher than that of the copper foil. Similarly, the tensile fracture strain of the resin layer alone is significantly higher than that of the copper foil composite. On the other hand, according to the present invention, the deformation behavior of the resin layer is transmitted to the copper foil, so that the ductility of the copper foil is improved, as described above. The tensile fracture strain of the copper foil composite can be correspondingly enhanced to 70 to 100% of the tensile fracture strain of the resin layer alone. When the ratio I/L is 0.7 or more, the press formability can be further improved.

The tensile fracture strain I of the copper foil composite is the tensile fracture strain obtained by the tensile test. And, when both the resin layer and the copper foil are broken at the same time, the value of this point is defined as the tensile fracture strain. When the copper foil is broken first, the value when the copper foil is broken is defined as the tensile fracture strain.

<Tg of Resin Layer>

Typically, the resin layer has decreased strength and adhesion strength at high temperature. So, it is difficult to satisfy (f₃×t₃)/(f₂×t₂)=>1 and 1<=33f₁/(F×T) at high temperature. Specifically, at the glass transition temperature (Tg) or more of the resin layer, the strength and the adhesion strength of the resin layer may be difficult to be kept. At the temperature lower than Tg, the strength and the adhesion strength of the resin layer tend to be easily kept. In other words, at the temperature lower than the glass transition temperature (Tg) (e.g. 5° C. to 215° C.) of the resin layer, the copper foil composite easily satisfies (f₃×t₃)/(f₂×t₂)=>1 and 1<=33f₁/(F×T). Here, at the higher temperature but lower than Tg, the strength and the adhesion strength of the resin layer may be decreased and satisfying the equations 1 and 2 tends to be difficult (see Examples 16 to 18 described later).

When the equations 1 and 2 are satisfied, it is found that the ductility of the copper foil composite can be maintained even at relatively high temperature (e.g., 40° C. to 215° C.) lower than Tg of the resin layer. If the ductility of the copper foil composite can be maintained even at relatively high temperature (e.g., 40° C. to 215° C.) but lower than Tg of the resin layer, excellent formability is shown even in a warm press forming. It is preferable that the temperature be higher for providing the resin layer with the good formability. Further, the copper foil composite is warm pressed to retain the shape after pressing (not to return to the original by elastic deformation). From this point of view, it is preferable that the ductility of the copper foil composite can be maintained at relatively high temperature (e.g., 40° C. to 215° C.) but lower than Tg of the resin layer.

If the copper foil composite comprises the adhesive agent layer and the resin layer, the lowest glass transition temperature (Tg) of the layer is used.

Example Production of Copper Foil Composite

A tough-pitch copper ingot was hot-rolled, was surface grinded to remove oxides, was cold-rolled, was annealed and acid-pickled repeatedly to reduce the thickness t₂ (mm) as shown in Table 1, was finally annealed to ensure the formability, and was rust-proofed using benzotriazole, whereby each copper foil was provided. A tension upon cold-rolling and rolling reduction conditions of the rolled material in a width direction were uniform so that the copper foil had uniform texture in the width direction. In the next annealing, a plurality of heaters were used to control the temperature so that a uniform temperature distribution was attained in the width direction, and the temperature of the copper was measured and controlled.

Furthermore, both surfaces of each resultant copper foil were surface-treated as shown in Table 1. Thereafter, each resin film (resin layer) shown in Table 1 was laminated thereon by vacuum pressing (pressing pressure of 200 N/cm²) at a temperature of (Tg of the resin layer+50° C.) or more to produce each copper foil composite having each layer structure shown in Table 1. In Example 5, an adhesive agent was used to laminate the copper foil and the resin film, thereby producing the copper foil composite.

In Table 1, Cu represents a copper foil, PI represents a polyimide film, and PET represents a polyethylene terephtalate film. Tgs of PI and PET were 220° C. and 70° C.

One surface of the copper foil (a surface not adhered to the resin layer) was Sn plated, and an opposite surface of the copper foil (a surface adhered to the resin layer) was surface-treated shown in Table 1. The conditions of the surface treatment were as follows:

Chromate treatment: a chromate bath (K₂Cr₂O₇: 0.5 to 5 g/L) was used, and electrolytic treatment was conducted at current density of 1 to 10 A/dm². The Cr oxide layer coating amount was set to be 35 μg/dm².

Ni coating+chromate treatment: a Ni plating bath (Ni ion concentration: 1 to 30 g/L Watts bath) was used, Ni plating was conducted at a plating bath temperature of 25 to 60° C. and at current density of 0.5 to 10 A/dm², and the chromate treatment was then conducted as described above. The thickness of the Ni coating was set to 0.010 μm.

Roughening treatment: a treatment liquid (Cu: 10 to 25 g/L, H2SO4: 20 to 100 g/L) was used, and electrolytic treatment was conducted at a temperature of 20 to 40° C. and at current density of 30 to 70 A/dm² for 1 to 5 seconds. Thereafter, a Ni—Co plating liquid (Co ion concentration: 5 to 20 g/L, Ni ion concentration: 5 to 20 g/L, pH: 1.0 to 4.0) was used to conduct Ni—Co plating at a temperature of 25 to 60° C. and at current density of 0.5 to 10 A/dm².

Sn plating: a phenolsulfonic acid bath containing 20 to 60 g/L of stannous oxide was used, Sn plating was conducted at a temperature of 35 to 55° C. and at current density of 2.0 to 6.0 A/dm². The thickness of the Sn plating layer was adjusted depending on electrodeposition time.

In each Example 24 to 27, after a non-bonding surface of the copper foil was Ni or Cu plated in the thickness shown in Table 1, Sn plating was conducted. The conditions of the Ni plating was the same as those in the above-described Ni coating. In the Cu plating, a copper plating bath containing 200 g/L of copper sulfate and 60 g/L of sulfuric acid was used and the conditions of temperature of 30° C. and a current density of 2.3 A/dm² were used.

In Example 28, after a non-bonding surface of the copper foil was Ni and Cu plated in the thickness shown in Table 1 in the stated order, Sn plating was conducted. The conditions of the Ni and Cu plating were the same as those in Examples 24 to 27.

In Example 21, a Ni—Zn layer was formed at a thickness of 0.30 μm on a non-bonding surface of the copper foil, and Sn plating was conducted on a surface of the Ni—Zn layer. On the other hand, a Ni—Zn layer was formed at a thickness of 0.030 μm on a bonding surface of the copper foil, and a Cr oxide layer was formed at an coating amount of 35 μg/dm² by the chromate treatment. The Ni—Zn layer was formed using a Ni—Zn plating bath (Ni ion concentration: 15 to 20 g/L, Zn ion concentration: 10 to 20 g/L) was used and the conditions of the plating liquid temperature of 50° C. and a current density of 4.0 A/dm² were used. As a result of analyzing the Ni—Zn layer, the alloy composition was Ni:Zn=75:25 (wt %).

In Example 22, a Ni—P layer was formed at a thickness of 0.30 μm on a non-bonding surface of the copper foil, and Sn plating was conducted on a surface of the Ni—P layer. On the other hand, a Ni—P layer was formed at a thickness of 0.030 μm on a bonding surface of the copper foil, and a Cr oxide layer was formed at an coating amount of 35 μg/dm² on the surface of the Ni—P layer by the chromate treatment. The Ni—P layer was formed using a Ni—P plating bath (Ni ion concentration: 15 to 20 g/L, P ion concentration: 5 g/L) to conduct plating at a plating liquid temperature of 50 to 60° C. and at current density of 4 A/dm². As a result of analyzing the Ni—P layer, the alloy composition was Ni:P=95:5 (wt %).

In Example 23, a Ni—Sn layer was formed at a thickness of 0.30 μm on a non-bonding surface of the copper foil, and Sn plating was conducted on a surface of the Ni—Sn layer. On the other hand, a Ni—Sn layer was formed at a thickness of 0.030 μm on a bonding surface of the copper foil, and a Cr oxide layer was formed at an coating amount of 35 μg/dm² on the surface of the Ni—Sn layer by the chromate treatment. The Ni—Sn layer was formed using a Ni—Sn plating bath (Ni ion concentration: 15 to 20 g/L, Sn ion concentration: 10 to 15 g/L) was used to conduct plating at a plating liquid temperature of 45° C. and at current density of 4.0 A/dm². As a result of analyzing the Ni—Sn layer, the alloy composition was Ni:Sn=80:20 (wt %).

The coating amount of the Cr oxide layer and each thickness of the Ni layer, the Cu layer, the Ni alloy layer and the Sn layer were measured by a fluorescence X-ray Coating thickness gauge (manufactured by SII Nano Technology Inc., model SEA5100). Each sample was measured for 5 times, and an average value was taken as the coating amount (thickness).

The mass of each metal determined quantitatively by the above-described method was converted into each thickness of the Ni layer, the Cu layer, the Ni alloy layer and the Sn layer using known specific gravity.

<Tensile Test>

A plurality of strip test specimens each having a width of 12.7 mm were produced from the copper foil composite. As to the copper foil and the resin film of the tensile test, 12.7 mm wide strip test specimens were produced from the copper foil alone and the resin film alone before lamination.

Using a tensile tester, the tensile test was conducted in a direction parallel to the rolling direction of the copper foil in accordance with JIS-Z2241. The test temperature upon each tensile test is shown in Table 1.

<180° Peel Test>

A 180° peel test was conducted to measure the 180° peeling strength f₁. A plurality of peel test specimens each having a width of 12.7 mm were produced from the copper foil composite. The surface of the copper foil in the test specimen was fixed on a SUS plate, and the resin layer was peeled in a direction at an angle of 180°. In Examples where the copper foils were disposed on both surfaces of the resin layer, after the copper foil at one surface was removed, the copper foil on the opposite surface was fixed on the SUS plate and the resin layer was peeled in a direction at angle of 180°. The other conditions were in accordance with JIS-05016.

Although the copper foil layer was peeled in accordance with JIS standard, the resin layer was peeled in Examples in order to minimize the effects of the thickness and the stiffness of the copper foil.

<Evaluation of Formability>

The formability was evaluated using a cup test device 10 shown in FIG. 2. The cup test device 10 comprised a pedestal 4 and a punch 2. The pedestal 4 had a frustum slope. The frustum was tapered from up to down. The frustum slope was tilted at an angle of 60° from a horizontal surface. The bottom of the frustum was communicated with a circular hole having a diameter of 15 mm and a depth of 7 mm. The punch 2 was a cylinder and had a tip in a semispherical shape with a diameter of 14 mm. The semispherical tip of the punch 2 could be inserted into the circular hole of the frustum.

A connection part of the tapered tip of the frustum and the circular hole at the bottom of the frustum was rounded by a radius (r)=3 mm.

The copper foil composite was punched out to provide the test specimen 20 in a circular plate shape with a diameter of 30 mm, and was disposed on the slope of the frustum of the pedestal 4. The punch 2 was pushed down on the top of the test specimen 20 to insert it into the circular hole of the pedestal 4. Thus, the test specimen 20 was formed in a conical cup shape.

In the case the resin layer was disposed on one surface of the copper foil composite, the copper foil composite was disposed on the pedestal 4 such that the resin layer was faced upward. In the case the resin layers were disposed on both surfaces of the copper foil composite, the copper foil composite was disposed on the pedestal 4 such that the resin layer bonded to the M surface was faced upward. In the case the both surfaces of the copper foil composite were made of Cu, either surface might be faced upward.

After molding, the crack of the copper foil in the test specimen 20 was visually identified. The formability was evaluated the following scales: Excellent: the copper foil was not cracked and had no wrinkles.

Good: the copper foil was not cracked but had some wrinkles.

Not Good: the copper foil was cracked.

<Evaluation of Corrosion Resistance>

Salt water having a sodium chloride concentration of 5±1 wt %, pH=6.5 to 7.2 at 35±2° C. and pressure of 98±10 KPa was sprayed onto the surface of the copper foil laminate on which the resin layer was not laminated for 460 hours, and then appearance was visually observed. Presence or absence of the copper foil component on the surface was analyzed using XPS.

Excellent: the copper foil was not tarnished and was not exposed (no copper foil component was detected from the surface)

Good: the copper foil was whitely tarnished and not exposed (no copper foil component was detected from the surface)

Not Good: the copper foil was blackly tarnished by oxidation, or tarnished to green by rust; the copper foil was exposed (a copper foil component was detected from the surface)

<Evaluation of Electric Contact Properties>

Contact resistance on the surface of the copper foil on which the resin layer was not laminated was measured after each test specimen was heated at 180° C. for 1000 hours in the atmosphere. The measurement was conducted using an electric contact simulator CRS-1 manufactured by Yamazaki Seiki Co., Ltd. by the four terminal method. Probe: gold probe, contact load: 40 g, sliding speed: 1 mm/min and sliding distance: 1 mm.

Good: contact resistance was less than 10 mΩ

Not good: contact resistance was 10 mΩ or more

The results are shown in Tables 1 and 2. The test temperatures in Table 1 show the temperatures of the evaluation of F, f₁, f₂, f₃ and formability.

TABLE 1 Sn layer Surface thickness Pressing treatment on coper pressure Struc- of copper foil surface upon ture of Tg of Test foil opposite to lami- coppre resin temper- at resin resin layer nation foil layer ature F T f1 f2 t2 f3 t3 layer side (μm) (N/cm2) composite (° C.) (° C.) (MPa) (mm) (N/mm) (MPa) (mm) (MPa) (mm) Example 1 Roughening 1.2 200 Cu/ 70 25 170 0.067 2.15 128 0.017 80 0.050 treatment PET Example 2 Chromate 1.2 200 Cu/ 70 25 141 0.067 1.01 128 0.017 80 0.050 PET Example 3 Ni coating + 1.2 200 Cu/ 70 25 150 0.067 1.57 128 0.017 80 0.050 Chromate treatment PET Example 4 Sn 1.2 200 Cu/ 70 25 142 0.020 0.78 115 0.008 80 0.012 PET Example 5 Bonding agent 1.2 200 Cu/ 70 25 118 0.020 0.50 115 0.008 80 0.012 PET Example 6 Ni coating + 0.22 200 Cu/ 70 25 137 0.067 1.57 128 0.017 80 0.050 Chromate treatment PET Example 7 Ni coating + 0.8 200 Cu/ 70 25 137 0.067 1.57 128 0.017 80 0.050 Chromate treatment PET Example 8 Ni coating + 2.1 200 Cu 70 25 137 0.067 1.57 128 0.017 80 0.050 Chromate treatment PET Example 9 Ni coating + 2.8 200 Cu/ 70 25 137 0.067 1.57 128 0.017 80 0.050 Chromate treatment PET Example 10 Ni coating + 1.2 200 Cu/ 70 25 123 0.044 1.57 125 0.012 80 0.032 Chromate treatment PET Example 11 Ni coating + 1.2 200 Cu/ 70 25 140 0.067 1.57 128 0.017 80 0.050 Chromate treatment PET Example 12 Ni coating + 1.2 200 Cu/ 70 25 140 0.135 1.57 110 0.035 80 0.100 Chromate treatment PET Example 13 Ni coating + 1.2 200 Cu/ 70 25 119 0.210 1.57 120 0.035 80 0.175 Chromate treatment PET Example 14 Ni coating + 1.2 200 Cu/ 70 25 134 0.285 1.57 120 0.035 80 0.250 Chromate treatment PET Example 15 Ni coating + 1.2 200 Cu/ 220 25 144 0.067 1.57 128 0.017 100 0.050 Chromate treatment PI Example 16 Ni coating + 1.2 200 Cu/ 70 50 120 0.135 0.80 120 0.035 80 0.100 Chromate treatment PET Example 17 Ni coating + 1.2 200 Cu/ 220 150 130 0.067 0.70 128 0.017 100 0.050 Chromate treatment PI Example 18 Ni coating + 1.2 200 Cu/ 220 200 75 0.067 0.50 128 0.017 100 0.050 Chromate treatment PI Example 19 Ni coating + 1.2 200 Cu/ 70 25 160 0.067 1.57 128 0.017 80 0.050 Chromate treatment PET/ Cu Example 20 Ni coating + 1.2 200 Cu/ 220 25 160 0.067 1.57 128 0.017 100 0.050 Chromate treatment PI/ Cu Example 21 Ni—Zn Ni—Zn 200 Cu/ 70 25 137 0.067 1.57 128 0.017 80 0.050 (0.030 μm) + (0.30 μm)/ PET Chromate treatment Sn0.8 μm Example 22 Ni—P Ni—P 200 Cu/ 70 25 137 0.067 1.57 128 0.017 80 0.050 (0.030 μm) + (0.30 μm)/ PET Chromate treatment Sn0.8 μm Example 23 Ni—Sn Ni—Sn 200 Cu/ 70 25 137 0.067 1.57 128 0.017 80 0.050 (0.030 μm) + (0.30 μm)/ PET Chromate treatment Sn0.8 μm Example 24 Ni coating + Ni0.3 μm/ 200 Cu/ 70 25 137 0.067 1.57 128 0.017 80 0.050 Chromate treatment Sn0.8 μm PET Example 25 Ni coating + Ni1.5 μm/ 200 Cu/ 70 25 137 0.067 1.57 128 0.017 80 0.050 Chromate treatment Sn0.8 μm PET Example 26 Ni coating + Cu0.2 μm/ 200 Cu/ 70 25 137 0.067 1.57 128 0.017 80 0.050 Chromate treatment Sn0.8 μm PET Example 27 Ni coating + Cu1.5 μm/ 200 Cu/ 70 25 137 0.067 1.57 128 0.017 80 0.050 Chromate treatment Sn0.8 μm PET Example 28 Ni coating + Ni0.6 μm/ 200 Cu/ 70 25 137 0.067 1.57 128 0.017 80 0.050 Chromate treatment Cu0.3 μm/ PET Sn1.2 μm Comp. No 1.2 200 Cu/ 220 25 158 0.087 0.20 120 0.035 137 0.052 Example 1 PI Comp. No 1.2 100 Cu/ 220 25 139 0.135 0.40 120 0.035 100 0.100 Example 2 PI Comp. Chromate treatment 1.2 200 Cu/ 220 25 120 0.085 1.01 140 0.035 87 0.050 Example 3 PI Comp. No 1.2 100 Cu/ 220 25 70 0.135 0.20 111 0.035 43 0.100 Example 4 PI Comp. Chromate treatment 0.1 200 Cu/ 220 25 70 0.135 1.01 111 0.035 43 0.100 Example 5 PET

TABLE 2 Electric 33*f1/ (f3 × t3)/ Corrosion contact (F × T) (f2 × t2) L I I/L Formability resistance properties Example 1 6.23 1.84 80 37 0.46 Good Good Good Example 2 3.53 1.84 80 32 0.40 Good Good Good Example 3 5.16 1.84 80 35 0.44 Good Good Good Example 4 9.06 1.04 80 32 0.40 Good Good Good Example 5 6.99 1.04 80 32 0.40 Good Good Good Example 6 5.64 1.84 80 35 0.44 Good Good Good Example 7 5.64 1.84 80 35 0.44 Good Good Good Example 8 5.64 1.84 80 34 0.43 Good Excellent Good Example 9 5.64 1.84 80 34 0.43 Good Excellent Good Example 10 9.57 1.71 80 61 0.76 Excellent Good Good Example 11 5.52 1.84 80 58 0.73 Excellent Good Good Example 12 2.74 2.08 80 40 0.50 Good Good Good Example 13 2.07 3.33 80 38 0.48 Good Good Good Example 14 1.36 4.76 80 32 0.40 Good Good Good Example 15 5.37 2.30 107 89 0.83 Excellent Good Good Example 16 1.63 1.90 95 23 0.24 Good Good Good Example 17 2.65 2.30 114 30 0.26 Good Good Good Example 18 3.28 2.30 150 35 0.23 Good Good Good Example 19 4.83 1.84 80 32 0.40 Good Good Good Example 20 4.83 2.30 107 89 0.83 Excellent Good Good Example 21 5.64 1.84 80 35 0.44 Good Good Good Example 22 5.64 1.84 80 35 0.44 Good Good Good Example 23 5.64 1.84 80 35 0.44 Good Good Good Example 24 5.64 1.84 80 35 0.44 Good Good Good Example 25 5.64 1.84 80 35 0.44 Good Good Good Example 26 5.64 1.84 80 35 0.44 Good Good Good Example 27 5.64 1.84 80 35 0.44 Good Good Good Example 28 5.64 1.84 80 35 0.44 Good Good Good Comparative Example 1 0.48 1.70 68 14 0.21 Not good Good Good Comparative Example 2 0.70 2.38 107 11 0.10 Not good Good Good Comparative Example 3 3.27 0.89 107 19 0.18 Not good Good Good Comparative Example 4 0.70 1.11 150 8 0.05 Not good Good Good Comparative Example 5 3.53 1.11 150 32 0.21 Not good Not good Not good

As apparent from Tables 1 and 2, in each Example, both (f₃×t₃)/(f₂×t₂)=>1 and 1<=33f₁/(F×T) were satisfied, and the formability was excellent. Also, in each Example, the electric contact properties and the corrosion resistance were excellent.

When Example 12 was compared with Example 16 each having the same structure of the copper foil laminate, the value of (f₃×t₃)/(f₂×t₂) in Example 12 was greater than that in Example 16, because F and so on were measured by conducting the tensile test at room temperature (about 25° C.) in Example 12,. It can be concluded that the resin layer in Example 16 was weak (i.e., f₃ is small) due to high test temperature.

On the other hand, in Comparative Example 1 where the resin film was laminated without conducting the surface treatment of the copper foil, the adhesion strength was decreased, 33f₁/(F×T) was less than 1, and the formability was poor.

In Comparative Examples 2 and 4 where the pressing pressure upon lamination was decreased to 100 N/cm², the adhesion strength was decreased, 33f₁/(F×T) was less than 1, and the formability was poor.

In Comparative Example 3 where the thickness of the resin film was decreased, the strength of the resin film was decreased as compared with the copper foil and (f₃×t₃)/(f₂×t₂) was less than 1, and the formability was poor.

In Comparative Example 5 where the thickness of the Sn plating layer on the surface not adhered to the resin layer, the electric contact properties and the corrosion resistance were poor. 

1. A copper foil composite comprising a copper foil and a resin layer laminated thereon, satisfying an equation 1: (f₃×t₃)/(f₂×t₂)=>1 wherein t₂ (mm) is a thickness of the copper foil, f₂ (MPa) is a stress of the copper foil under tensile strain of 4%, t₃ (mm) is a thickness of the resin layer, f₃ (MPa) is a stress of the resin layer under tensile strain of 4%, and an equation 2:1<=33f₁/(F×T) wherein f₁ (N/mm) is 180° peeling strength between the copper foil and the resin layer, F(MPa) is strength of the copper foil composite under tensile strain of 30%, and T (mm) is a thickness of the copper foil composite, wherein a Sn layer having a thickness of 0.2 to 3.0 μm is formed on a surface of the copper foil on which the resin layer is not laminated.
 2. The copper foil composite according to claim 1, wherein the equations 1 and 2 are true at the temperature lower than the glass transition temperature of the resin layer.
 3. The copper foil composite according to claim 1, wherein a ratio I/L of fracture strain I of the copper foil composite to fracture strain L of the resin layer alone is 0.7 to
 1. 4. The copper foil composite according to claim 1, wherein a Ni layer or a Cu layer is formed between the Sn layer and the copper foil, or a Ni layer and a Cu layer are formed between the Sn layer and the copper foil in the order of the Ni layer and the Cu layer from the copper foil, and wherein the Ni layer and the Cu layer each have a thickness of 0.1 to 2.0 μm.
 5. (canceled)
 6. (canceled)
 7. The copper coil composite according to claim 1, wherein a Ni alloy layer or a Cu layer is formed between the Sn layer and the copper foil, or a Ni alloy layer and a Cu layer are formed between the Sn layer and the copper foil in the order of the Ni alloy layer and the Cu layer from the copper foil, and wherein the Ni alloy layer and the Cu layer each have a thickness of 0.1 to 2.0 μm.
 8. A formed product obtained by working the copper foil composite according to claim
 1. 9. A method of producing a formed product comprising working the copper foil composite according to claim
 1. 10. The copper foil composite according to claim 2, wherein a ratio I/L of fracture strain I of the copper foil composite to fracture strain L of the resin layer alone is 0.7 to
 1. 11. The copper foil composite according to claim 2, wherein a Ni layer or a Cu layer is formed between the Sn layer and the copper foil, or a Ni layer and a Cu layer are formed between the Sn layer and the copper foil in the order of the Ni layer and the Cu layer from the copper foil, and wherein the Ni layer and the Cu layer each have a thickness of 0.1 to 2.0 μm.
 12. The copper coil composite according to claim 2, wherein a Ni alloy layer or a Cu layer is formed between the Sn layer and the copper foil, or a Ni alloy layer and a Cu layer are formed between the Sn layer and the copper foil in the order of the Ni alloy layer and the Cu layer from the copper foil, and wherein the Ni alloy layer and the Cu layer each have a thickness of 0.1 to 2.0 μm.
 13. A formed product obtained by working the copper foil composite according to claim
 2. 14. A method of producing a formed product comprising working the copper foil composite according to claim
 2. 15. The copper foil composite according to claim 3, wherein a Ni layer or a Cu layer is formed between the Sn layer and the copper foil, or a Ni layer and a Cu layer are formed between the Sn layer and the copper foil in the order of the Ni layer and the Cu layer from the copper foil, and wherein the Ni layer and the Cu layer each have a thickness of 0.1 to 2.0 μm.
 16. The copper coil composite according to claim 3, wherein a Ni alloy layer or a Cu layer is formed between the Sn layer and the copper foil, or a Ni alloy layer and a Cu layer are formed between the Sn layer and the copper foil in the order of the Ni alloy layer and the Cu layer from the copper foil, and wherein the Ni alloy layer and the Cu layer each have a thickness of 0.1 to 2.0 μm.
 17. A formed product obtained by working the copper foil composite according to claim
 3. 18. A method of producing a formed product comprising working the copper foil composite according to claim
 3. 19. A formed product obtained by working the copper foil composite according to claim
 4. 20. A method of producing a formed product comprising working the copper foil composite according to claim
 4. 21. A formed product obtained by working the copper foil composite according to claim
 7. 22. A method of producing a formed product comprising working the copper foil composite according to claim
 7. 